1. By means of Q-switched ruby-laser flash excitation, the photooxidation of P870 in the reaction-center complex isolated from Rhodopseudomonas spheroides takes place within 1 μsec. The reduction of photooxidized P870 in the dark follows a first-order kinetics, with a pseudo first-order rate constant of 1.85×10 8 l×mole -1×sec -1 and an activation energy of 6 kcal/mole. 2. Through an electrostatic interaction of the bacteriochlorophyll reaction-center complex and mammalian cytochrome c, an intimate contact between the two components resulted, and a collision-independent electron-transfer with a halftime of 25 μsec can be attained by laser-flash excitation. The absorbance changes at 870 and 550 nm indicated a good stoichiometry of the reaction. The oxidation of the c-type cytochrome in cells of Rps. spheroides (R-26 mutant) has a halftime of 12 μsec. 3. The portion of P870 which recovered rapidly was closely related to the mole ratio of cytochrome/P870. Complete recovery with a halftime of 25 μsec occurred when the cytochrome/P870 ratio was above approx. 10. At cytochrome/P870 ratios lower than 10, only the fraction of the reaction-center complex which have cytochromes bound at the active site can recover with the rapid decay time. Ultrafiltration measurements showed that each particle of the reaction-center complex can bind approx. 24 cytochrome molecules. 4. An electro static interaction is expected simply from the large difference between the isoelectric points of cytochrome c ( ≧ 10) and that of the reaction-center complex (4.1 measured by electro-focusing). The electro static interaction was further evidenced by the effects of pH, ionic strength, and by polylysine displacement of binding sites on the coupled oxidation of ferrocytochrome c by P870. From the limiting polylysine concentration giving complete blocking of cytochrome coupling, it was calculated that each reaction-center complex with a particle weight of 6.5×10 5 contained approx. 500 negative charges. 5. Arrhenius plot of the first-order rate constants vs. the reciprocal absolute temperature yielded an activation energy of 12 kcal/mole for the cytochrome/P870 reaction, which is presumably the energy needed for cytochrome to achieve the most favorable orientation for the rapid electron transfer. Below the freezing temperature of the sample, the cytochrome reaction appeared to be uncoupled. The temperature dependence is consistent with the effect of viscosity on the reaction rate. 6. Double flash excitations spaced 200 μsec apart showed that at a cytochrome/P870 ratio of 24, the first flash caused maximum oxidation, indicating that all the reaction-center particles have at least one cytochrome attached to the active site. However, only 60% of the particles have a second cytochrome closely attached and capable of undergoing the rapid electron transport.